Communications Continues To Inspire Technology Advances

From the latest wireless standards and test equipment to cutting-edge process technologies and modulation approaches, RF and microwave firms are leading an exciting evolution while providing some possible game-changing technology approaches.

What is in this article?:

The RF/microwave fields are some of the fastest and most innovative fields in technology. New semiconductor, standards, and communication technologies emerge every year, giving designers an exciting new landscape and impressive new tools.

In the microwave and RF arena, semiconductors, communications approaches, and the wireless standards they use are either the focus of research and development or the inspiration behind developments in other areas. Advances in RF semiconductors give designers access to higher frequencies, power, dynamic range, and lower noise parameters, enabling them to design the next generation of RF electronics. Meanwhile, wireless standards provide a roadmap for companies and designers to coordinate their efforts and provide relevant technologies that are compatible with a changing and expanding infrastructure.

Evolving communication techniques allow designers to cleverly use the present technology beyond previously thought boundaries, increasing range, throughput, and signal-to-noise ratio (SNR). By focusing on new innovations and developments surrounding these pillars of the RF/microwave industry, it is possible to gain insight into what the industry’s landscape will look like in the next few years.

RF semiconductor research has recently explored new materials like graphene, carbon nanotubes, metamaterials, superconductors, and even textiles. New methods of stacking ICs, known as 3D ICs, also are a hot topic of research. These avenues may lead to advances in a few years. But they aren’t yet ready to help extend the present capabilities of RF components to the next level in current markets. A few companies, such as Peregrine Semiconductor, are using proven technologies with small leaps in development to provide roadmapped improvements that will be available for next-generation parts.

Peregrine’s silicon-on-insulator (SOI) UltraCMOS 10 is such a process. Peregrine claims it improves 20% consistently every year and is able to support LTE-Advanced (LTE-A) operational requirements (Fig. 1). In many markets, it is thought to have the potential to outpace gallium arsenide (GaAs) as the semiconductor of choice. As noted by Duncan Pilgrim, director of strategic marketing, “When silicon matches GaAs in a market, it takes over.”

The UltraCMOS 10 technology boasts a high-resistance substrate, which allows RF device speeds while incorporating analog and digital blocks on the same substrate. The ability to combine these three regimes lowers costs, increases speeds, and allows for higher yields with advanced integration. To implement the improvements to the UltraCMOS line of products, Peregrine partnered with Siotec and GLOBALFOUNDRIES to create the 130-nm UltraCMOS 10 process and help accelerate process-node reduction.

Good electrostatic-discharge (ESD) performance of 2000 V and potentially higher on every pin is another benefit of UltraCMOS over comparable GaAs technologies. Peregrine is currently testing power amplifiers (PAs) with performance specifications that could be comparable to GaAs PAs and even exceed them, as SOI-based RF components do not degrade linearity as a function of power. The development of SOI PAs along with tuners and switches could open the doors for a complete SOI RF front end, allowing for a complete solution in a single technology. Testing also is being done on devices that, in the next few years, could reach speeds to 50 GHz using SOI technology. The next generation of wireless standards is a driving force for RF semiconductor technologies to enhance the capability of RF switches/tuners while lowering the cost of components. Long Term Evolution Advanced (LTE-A), for example, pushes the boundaries of RF semiconductors by allowing bandwidths to 100 MHz and multiple-input multiple-output (MIMO) operation.

Developed by the 3rd Generation Partnership Project (3GPP), LTE-A is designed to meet or exceed the requirements of the International Telecommunication Union (ITU) for the fourth generation (4G) of radio communication—a standard known as IMT-Advanced. Starting with Release 10 and including later releases, LTE-A is described with higher capacity and increased data rates up to 3 Gb/s for downlink (DL) and 1.5 Gb/s for uplink (UL). Improved performance for cell edges, higher spectral efficiency, and an increase in simultaneous active subscribers also are critical improvements in the Advanced standard over the previous LTE standard. The main new functional additions of the standard include MIMO antenna techniques to 8×8, enhanced uplink, support for relay nodes (RNs), and carrier-aggregation capabilities.

Carrier aggregation offers the ability to use the fragmented bandwidths of a variety of carriers and aggregate them to the 100-MHz maximum bandwidth (Fig. 2). This helps in situations where certain carriers’ bandwidth offerings don’t meet necessary DL or UL requirements for a particular device, but multiple carriers combined could provide adequate data rates. By using an RN as a part of a telecommunications system, signals could be passed from a transmitter potentially much further away or with a much weaker signal to a device that otherwise wouldn’t be able to communicate with adequate signal to noise for high data rates.

There are different types of relays. A Layer 1 relay is merely a repeater that amplifies the signals from transmitter to device while a Layer 2 relay demodulates the signal and modulates/transmits the signal with higher power for noise-reduction purposes. For its part, a Layer 3 relay completely deconstructs/reconstructs the communication signals in the link for higher noise reduction and standards specification benefits. A MIMO antenna system coordinates the frequency capabilities from multiple antennas to allow data rates far greater than a single antenna could accomplish. This multiple-bandwidth operation creates a variety of design difficulties stemming from working with such a large range of RF signals and having to switch and tune the variety of antennas simultaneously. The benefit is that the channels for communication are doubled with each additional antenna that is added to the matrix. As a result, data rates can hit the 3 Gb/s defined by the standard.